KR100266616B1 - High power induction heating device - Google Patents

Abstract

PURPOSE: A high output induction heat cooker is provided to easily output a power suitable to a property of a vessel by detecting a current flowing through a diode. CONSTITUTION: A rectifier(10) rectifies an alternating current voltage and outputs a rectified direct current voltage. A filter(11) filters the rectified direct current voltage from the rectifier(10). An inverter(12) receives the filtered voltage from the filter(11) and provides a resonant voltage. A heating coil(Lr) induces and heats a wirling current to a cooking vessel(17). Resonant capacitors(Cr1,Cr2) resonates with the heating coil(Lr). An input current detector(13) detects an input current. A diode conducting current detector(20) detects a conducting current flowing through a diode of the inverter(12). A controller(14) controls the conducting current flowing the diode to operate from a smallest set value to a largest set value. A switching frequency generator(15) generates a switching frequency according to a control signal from the controller(14). A driver(16) generates a driving signal according to a switching frequency of the switching frequency generator(15).

Description

High Power Induction Cooker

The present invention relates to a high output induction cooker, and more particularly, to a high output induction cooker capable of outputting power in accordance with the characteristics of the container by detecting a current flowing through a diode of an inverter to prevent damage to a switching element and operate safely. will be.

1 is a circuit diagram showing the configuration of a general induction heating cooker, as shown in the rectifier 10 for receiving and rectifying the AC power (AC); A filter unit 11 which receives the rectified power of the rectifier 10 and filters it; An inverter unit 12 for heating the container 17 by receiving the filtered power from the filter unit 11 and switching it; A heating coil Lr for heating the vessel 17; Resonant capacitors Cr1 and Cr2 which resonate in series with the heating coil Lr; An input current detector 13 for detecting power consumed by the input AC power; A control unit 14 for receiving a detection signal of the input current detector 13 and controlling a desired power to be output accordingly; A switching frequency generator 15 for generating a switching frequency according to the control signal of the controller 14; The drive unit 16 receives the switching frequency of the switching frequency generator 15 and applies the driving signal to the inverter unit 12.

The inverter unit 12 includes first and second switching devices SW1 and SW2 that receive a switching frequency to the gate and are switched accordingly; In order to protect the first and second switching elements (SW1), (SW2) are respectively composed of diodes (D1), (D2) and capacitors (C2), (C3) connected in parallel, Describe the operation.

First, the rectifying unit 10 receives the AC power and rectifies it to generate a DC voltage according thereto, and the filter unit 11 receives the DC power of the rectifying unit 10 and filters the filtered voltage according to the inverter unit. To (12).

At this time, the input current detector 13 detects an input current to detect power consumed by the AC power, and the controller 14 receives a detection signal of the input current detector 13 and receives a predetermined control signal accordingly. The switching frequency generator 15 is applied.

Accordingly, the switching frequency generator 15 receives a predetermined control signal from the controller 14 to generate a switching frequency according to the switching frequency, and applies the switching frequency to the drive unit 16, thereby driving the drive unit 16. ) Receives a switching frequency from the switching frequency generator 15 and applies a driving signal to the inverter 12.

Accordingly, as the switching elements SW1 and SW2 of the inverter unit 12 alternately operate according to the drive signal of the drive unit 16, the electric induction effect due to the magnetic field generated by the heating coil Lr. An eddy current is induced in the vessel 17 to heat the vessel 17. At this time, the magnetic field generated by the heating coil Lr is heated coil Lr as the switching elements SW1 and SW2 alternately drive. The over resonance capacitors Cr1 and Cr2 are generated by series resonance.

If the equivalent model of the heating coil (Lr) and the vessel 17 is composed of a resistor and a reactor, power consumption is calculated as follows.

If R1 (resistance of heating coil) + Roven (resistance of vessel 17) = Rin and the power consumption (P) is obtained from the reactor value Lr,

P = (Vin / Zin) ² × Rin ------ (Eq. 1)

Vin = SW1on / (SW1on + SW1off) × Vd (Input voltage) ----- (Equation 2)

Rin = R1 (Resistance of heating coil) + Roven -------- (Equation 3)

Zin = -------- (Equation 4)

Where resonant frequency ( Power in the band is maximum and the actual switching frequency is ZVS f _r (Switching frequency) ≻ f ₀ Switch in the phosphorus region.

In addition, the maximum power is output differently according to the resistance value.

That is, when switching at the resonance frequency, the maximum output power is small when the Rin value is large, and the maximum power is large when the Rin value is small.

If the Rin value is large when the user switches at the desired output power, that is, when the bottom of the container 17 is thick, as shown in FIG.

Therefore, when the frequency is lowered to increase the output power, the ZVS is not formed, and thus the switching devices SW1 and SW2 may be damaged, and when the input resistance Rin is small, that is, the bottom of the container 17 is usually 2b has an operating characteristic capable of outputting up to 3000W of maximum output power at resonance.

However, in the conventional apparatus operating as described above, the maximum power that can be output may vary depending on the thickness of the container, and when the power that can be output is exceeded, a short current flows to the switch, which may cause breakage of the switch. There is a problem, and the switch and the diode are packaged in consideration of the cost and the number of times in order to detect the current of the diode configured in parallel with the switch so that the short current does not occur, and output the proper power that does not damage the switch. Because of this, there is a problem in measuring current.

Therefore, the present invention devised in view of the above problems is to prevent the breakage of the switching device to operate safely and the current transformer in the inverter using the switching device and the diode in one package without separating the switching device and the diode device The purpose of the present invention is to provide a high-power induction cooker that detects the current flowing through the diode and outputs power corresponding to the characteristics of the container.

1 is a circuit diagram showing the configuration of a conventional general induction heating cooker.

2 is a waveform diagram of current in resonance according to a difference in magnetic container thickness in FIG. 1;

3 is a circuit diagram showing the configuration of the high-power induction cooker of the present invention.

FIG. 4 is a circuit diagram showing the structure of the diode conduction current detecting section in FIG.

* Description of the symbols for the main parts of the drawings *

10: rectifier section 11: filter section

12: Inverter unit 13: Input current detector

14: control unit 15: switching frequency generator

16: drive part 17: container

20: diode conduction current detector

The present invention for achieving the above object is a rectifying unit for rectifying the AC power input to output a DC voltage; A filter unit for receiving a DC voltage from the rectifier and filtering the DC voltage; An inverter unit which receives the filtered voltage of the filter unit and switches by a predetermined driving signal to provide a resonance voltage; A heating coil configured to induce an eddy current in the cooking vessel and heat the cooking vessel with electric induction by a magnetic field generated by the resonance voltage of the inverter unit; A resonance capacitor resonating with the heating coil by a switching operation of the inverter; An input current detector for detecting an input current; A diode conduction current detector for detecting a conduction current flowing through the diode of the inverter unit; A control unit which receives the detection signal of the input current unit and the detection signal of the diode conduction current detection unit and controls the conduction current flowing through the diode to operate between a minimum setting value and a maximum setting value; A switching frequency generator which receives a control signal of the controller and generates a switching frequency according to the control signal; And a drive unit configured to receive the switching frequency of the switching frequency generator and apply a driving signal to the switching device of the inverter unit.

Hereinafter, with reference to the accompanying drawings the operation and effects of an embodiment of a high-power induction cooker according to the present invention will be described in detail.

Figure 3 is a circuit diagram showing the configuration of the high-power induction cooker of the present invention, as shown in the rectifier 10 for rectifying the AC power input to output a DC voltage; A filter unit 11 for receiving a DC voltage from the rectifier 10 and filtering the DC voltage; An inverter unit 12 which receives the filtered voltage of the filter unit 11 and switches by a predetermined driving signal to provide a resonance voltage; A heating coil (Lr) for inducing an eddy current in the cooking vessel (17) for heating by inducing electric current by a magnetic field generated by the resonance voltage of the inverter unit (12); Resonant capacitors Cr1 and Cr2 resonating with the heating coil Lr by the switching operation of the inverter unit 12; An input current detector 13 for detecting an input current; A diode conduction current detection unit 20 for detecting a conduction current flowing through the diode D2 of the inverter unit 12; The control unit 14 receives the detection signal of the input current detection unit 13 and the detection signal of the diode conduction current detection unit 20 to control the conduction current flowing through the diode D2 to operate within the minimum and maximum setting values. Wow; A switching frequency generator 15 which receives a control signal of the controller 14 and generates a switching frequency according thereto; The drive unit 16 receives a switching frequency of the switching frequency generator 15 and applies a driving signal to the switching elements SW1 and SW2 of the inverter unit 12.

FIG. 4 is a circuit diagram showing an embodiment of the diode conduction current detecting unit 20. As shown therein, a second switch SW2 of the inverter unit 12 is used to detect conduction current of the diode D2. Current transformer CT connected in series; A first resistor (R11) and a first capacitor (C11) connected in parallel to the current transformer (CT) to reset the current transformer (CT); A diode D11 connected in series with the current transformer CT and detecting a current flowing through the second diode D2 of the inverter unit 12; A second resistor R22 and a second capacitor C22 connected in parallel to the current transformer CT to replace the current detected by the diode D11 with a voltage will be described. The operation of the present invention configured as described above will be described. .

First, the general operation is the same as in the prior art. That is, the rectifying unit 10 receives an AC power and rectifies it to output a DC voltage, and the filter unit 11 receives the DC voltage of the rectifying unit 10 to remove noise to convert the DC voltage to the inverter unit 12. ) Is applied.

At this time, the input current detector 13 detects an input current to detect power consumed by the AC power, and the controller 14 receives a detection signal of the input current detector 13 and receives a predetermined control signal accordingly. The switching frequency generator 15 is applied.

Accordingly, the switching frequency generator 15 receives a predetermined control signal from the controller 14 to generate a switching frequency according to the switching frequency, and applies the switching frequency to the drive unit 16, thereby driving the drive unit 16. ) Receives a switching frequency from the switching frequency generator 15 and applies a driving signal to the inverter 12.

Accordingly, as the first and second switching elements SW1 and SW2 of the inverter unit 12 alternately operate according to the drive signal of the drive unit 16, the magnetic field generated by the heating coil Lr is applied. By inducing an eddy current in the vessel 17 by the electric induction effect by the heating the vessel 17, wherein the magnetic field generated in the heating coil (Lr) is the switching element (SW1), (SW2) as the alternating drive The heating coil Lr and the resonant capacitors Cr1 and Cr2 are generated in series resonance.

That is, the controller 14 applies a predetermined control signal to the switching frequency generator 15 to detect the input current through the input current detector 13 and control the frequency according to the input current detector 13 to output the desired power. As a result, the switching frequency generator 15 transmits each frequency capable of alternately switching the first and second switching devices SW1 and SW2 of the inverter unit 12 to the drive unit 16, and then the drive. The unit 16 performs an operation of driving a signal capable of driving the first and second switching elements SW1 and SW2 of the inverter unit 12 to heat the container 17 to a desired output power. do.

However, since the internal resistance is large when the bottom of the vessel 17 is heated, the maximum power reaches 1500 W in the resonant frequency band as shown in FIGS. 2A and 2B, and when the maximum power is raised to 1500 W or more, the switching is performed. A short current flows through the elements SW1 and SW2, and the switching elements SW1 and SW2 are damaged.

Here, the container 17 having a thick bottom of the container 17 can be heated at a sufficiently fast time even when the output power is heated to 1500W, and according to the present invention, unlike the conventional art, the diode conduction current detection unit 20 is installed to provide the inverter unit ( The current flowing through the second diode D2 of 12) is detected, and the control unit 14 receives the detection current of the diode conduction current detector 20 to control the detection current to operate between the minimum and maximum set values. .

At this time, the diode conduction current detection unit 20 detects the conduction current flowing through the diode D2 of the inverter unit 12 and designed so that the detected current is not less than 1V as shown in Table 1 below. It is possible to output power consumption accordingly.

division Input detector voltage Diode conduction current detector 0.9t 2 V 1 V 0.6t 2 V 1.5V

That is, as shown in Table 1, when the bottom of the vessel 17 has a thickness of 0.9 mm, the maximum of 1500 W and the bottom of the vessel 17 having a thickness of about 0.8 W are output by about 200 W. ), (SW2) is heated without damage.

As described in detail above, the present invention enables zero voltage switching when heating a thick container bottom in such a way that a diode can sense current only in an inverter using an IGBT device and a diode in a low-cost and easy-to-design package. By operating only in the region, it is possible to stably heat without damaging the switching element, and also by setting the region so as not to operate in the region of large switching loss even for small containers, there is an effect that it can be stably operated without damaging the switching element.

Claims (2)

A rectifier for rectifying an input AC power and outputting a DC voltage; A filter unit receiving a DC voltage from the rectifier and smoothing it; An inverter unit which receives the smoothing voltage of the filter unit and switches by a predetermined driving signal to provide a resonance voltage; A heating coil configured to induce an eddy current in the cooking vessel and heat the cooking vessel with electric induction by a magnetic field generated by the resonance voltage of the inverter unit; First and second resonant capacitors resonating with the heating coil by a switching operation of the inverter; An input current detector for detecting an input current; A diode conduction current detector for detecting a conduction current flowing through the diode of the inverter unit; A control unit which receives the detection signal of the input current unit and the detection signal of the diode conduction current detection unit and controls the conduction current flowing through the diode to operate between a minimum setting value and a maximum setting value; A switching frequency generator which receives a control signal of the controller and generates a switching frequency according to the control signal; And a drive unit configured to receive a switching frequency of the switching frequency generator and apply a driving signal to the switching device of the inverter unit. 2. The apparatus of claim 1, wherein the diode conduction current detecting unit comprises: a current transformer connected in series to a second switch of the inverter section for detecting the diode conduction current; A first resistor and a first capacitor connected in parallel to the current transformer to reset the current transformer; A first diode connected in series with the current transformer and detecting a current flowing through the diode of the inverter unit; And a second resistor and a second capacitor connected in parallel to the current transformer to replace the current detected by the first diode with a voltage.